CN111765683A - Movable assembled ice making pipe bracket and construction method thereof - Google Patents

Abstract

The invention discloses a movable assembled ice-making pipe bracket and a construction method thereof, wherein the movable assembled ice-making pipe bracket comprises a group of detachably connected ice-making pipe bracket module units; the ice making pipe bracket module unit comprises a group of supporting subunits, ice making pipe notches arranged on the supporting subunits, water permeable holes arranged at the lower parts of the supporting subunits, small circular water permeable holes arranged between adjacent supporting subunits, splicing jacks arranged at the periphery of the supporting subunits and a base bracket connected to the bottom of the supporting subunits. According to the invention, by arranging the ice-making pipe bracket module units, the site needing ice making is divided in a unit manner, so that the mass production and convenient installation are facilitated; by the arrangement of the supporting subunits, an installation space is provided, and water is convenient to freeze into a whole when being frozen into ice; through the setting of base support, both for supporting the subelement and providing the lower part and supporting, do benefit to long limit concatenation socket and the concatenation socket of minor face that connect on it simultaneously and be the concatenation between ice-making pipe bracket modular unit.

Description

Movable assembled ice making pipe bracket and construction method thereof

Technical Field

The invention belongs to the technical field of ice making construction, and particularly relates to a movable assembled ice making pipe bracket and a construction method thereof.

Background

At present, the ice sports stadium mostly adopts the mode that the ice making calandria is pre-buried in the concrete floor, needs to be mated with a plurality of process layers (such as concrete leveling layer, heating pipe and concrete pouring or sand filling layer, waterproof layer, heat preservation layer, ice making pipe and concrete protection layer), and constitutes the requirement of completing the whole ice making process. However, in a non-ice stadium, if various process layers above the temporary ice rink are required to be manufactured for construction, the construction process is complex, the construction site is greatly changed, the construction period is long, materials cannot be continuously utilized after the ice rink is removed, and a large amount of construction waste can be generated.

Disclosure of Invention

The invention provides a movable assembled ice making pipe bracket and a construction method thereof, which are used for solving the technical problems of convenient construction steps, easy operation and design, small change to the original site, easy material saving, reusability and the like of ice making in a temporary ice rink.

In order to achieve the purpose, the invention adopts the following technical scheme:

a movable assembled ice making pipe bracket comprises a group of ice making pipe bracket module units which are detachably connected; the ice making pipe bracket module unit comprises a group of supporting subunits, ice making pipe notches arranged on the supporting subunits, water permeable holes arranged at the lower parts of the supporting subunits, small circular water permeable holes arranged between adjacent supporting subunits, splicing jacks arranged at the periphery of the supporting subunits and a base bracket connected to the bottoms of the supporting subunits; an ice making calandria is arranged in the notch of the ice making pipe.

Furthermore, the supporting subunits are hexagonal or quadrangular columnar bodies, and the supporting subunits in the ice making pipe bracket module unit are integrally manufactured or detachably connected with the supporting subunits of the adjacent ice making pipe bracket module unit.

Furthermore, the opposite sides of the supporting subunits are provided with notches of the ice making tubes, and the side length of each supporting subunit is greater than the length of the notch of the ice making tube; the length of the notch of the ice making pipe is adapted to the diameter of the ice making calandria.

Furthermore, the notches of the ice making tubes are arranged in rows or columns, and the distance between the notches of the ice making tubes in adjacent rows or adjacent columns is suitable for the distance between the ice making tubes in the designed ice making rows.

Furthermore, the notch of the ice making pipe is an arc-shaped notch, and the radian of the arc-shaped notch is suitable for installing an ice making calandria; the distance between the top of the arc-shaped notch and the top of the support subunit is larger than the diameter and the length of the ice-making calandria.

Furthermore, the water permeable holes are round or polygonal holes and are arranged right below the supporting subunits; the opening area of the water permeable hole is suitable for the design section area when the ice making is conducted and the water is permeable.

Furthermore, the small circular water permeable holes are designed among three hexagonal supporting subunits or among four quadrilateral supporting subunits at intervals, and the small circular water permeable holes are arranged at the bottoms of the supporting subunits.

Furthermore, the splicing insertion openings comprise long-edge splicing insertion openings and short-edge splicing insertion openings, the long-edge splicing insertion openings are arranged on the base supports at the two opposite long edges of the ice making pipe bracket module unit, and the short-edge splicing insertion openings are arranged on the base supports at the two opposite short edges of the ice making pipe bracket module unit; the long edge splicing sockets arranged opposite to the edges are arranged in a staggered mode, and the short edge splicing sockets arranged opposite to the edges are arranged in a staggered mode.

Furthermore, the base supports are supporting plates, the shapes of the supporting plates are suitable for the ice pipe bracket module units, and the two base supports are detachably connected; the bottom surface interval of base support is provided with the fixed block.

Further, the construction method of the movable assembled ice making pipe bracket comprises the following specific steps:

step one, according to the size of the required ice surface, combining the size of ice making pipe bracket module units, and adopting a sufficient number of ice making pipe bracket module units to form the area required by the ice surface; the notches of the ice making tubes on the support subunits are arranged in rows or columns, and the sizes of the support subunits are correspondingly set according to the widths between the adjacent ice making tubes;

paving ice making pipe bracket module units, and splicing the long-edge splicing insertion openings or the short-edge splicing insertion openings with the ice making pipe bracket module units which are installed firstly by the aid of the later-installed ice making pipe bracket module units; the long-side splicing sockets or the short-side splicing sockets opposite to the joints of the adjacent ice pipe bracket module units are arranged in a staggered manner, and are inserted into the reserved grooves during installation, and the joints are ensured to be spliced into the supporting subunits;

laying ice making calandria along the notches of the ice making pipes on the support subunits, ensuring the linearity and fastening degree of the laid ice making pipes, and checking that all laid ice making pipe bracket module units are not separated; the bottom surface and/or the side surface of the notch of the ice making pipe are/is provided with a concave-convex surface or a rough surface;

step four, making ice and watering, wherein water permeates through the small circular water permeable holes and the water permeable holes and permeates below the base support, and the fixing block is connected with a lower structure to increase lateral anti-slip limit; when the water is frozen into ice, the water and the lower structure form a frozen whole;

and step five, when the ice field is dismantled, the ice making calandria is recycled after ice is melted, and the ice making pipe bracket module units can be dismantled one by one and then recycled or treated in a centralized way after being dismantled. The invention has the beneficial effects that:

1) according to the invention, by arranging the ice-making pipe bracket module units, the sites needing ice making are divided in a unit mode, so that batch production and convenient installation are facilitated, and the ice-making pipe bracket module units are convenient to move and carry, so that the construction time can be greatly saved;

2) according to the invention, through the arrangement of the supporting subunits, on one hand, an installation space is provided for the ice making calandria, the calandria can be fixed, and on the other hand, water can penetrate into the lower part through the water permeable holes and the small circular water permeable holes on the supporting subunits during ice making, so that the water can be conveniently frozen into ice to be solidified into a whole;

3) according to the invention, through the arrangement of the base support, not only is the lower support provided for the support subunit, but also the long-edge splicing insertion opening and the short-edge splicing insertion opening which are connected with the support subunit are beneficial to splicing and lifting among the ice making pipe bracket module units, and in addition, the arrangement of the fixed block at the lower part of the base support can further ensure the stability of the whole body in the horizontal direction;

the whole manufacturing and construction of the invention has little change to the current situation of the original stadium, and the invention has independent module units, can be freely assembled to reach the required size according to the ice surface requirement, and can greatly reduce the construction investment of the stadium on ice with independent functions; the method is convenient for batch construction, has higher accuracy and is easy to replace and disassemble; and can be repeatedly used after being dismantled, thereby reducing the generation of construction waste. Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention; the primary objects and other advantages of the invention may be realized and attained by the instrumentalities particularly pointed out in the specification.

Drawings

Fig. 1 is a plan view of an ice making tube tray module unit;

fig. 2 is a side view of an ice-making tube tray module unit;

fig. 3 is a top view of the support subunit.

Reference numerals: 1-water permeable hole, 2-ice making pipe notch, 3-small circular water permeable hole, 4-long edge splicing socket, 5-short edge splicing socket, 6-support subunit, 7-base support and 8-fixing block.

Detailed Description

Taking a certain temporary ice rink as an example, ice is needed to be made for venue operation, and a set of ice making pipe bracket module units and ice making calandria are applied to make ice in the design plan. As shown in fig. 1 and 2, the ice making tube holder module unit includes a set of supporting sub-units 6, ice making tube notches 2 formed in the supporting sub-units 6, water permeable holes 1 formed in the lower portions of the supporting sub-units 6, small circular water permeable holes 3 formed between adjacent supporting sub-units 6, splicing sockets formed in the periphery of the supporting sub-units 6, and a base holder 7 connected to the bottom of the supporting sub-units 6. The ice-making pipe bracket module unit is arranged in a square shape, and an ice-making pipe rack is arranged in an ice-making pipe notch 2 on the ice-making pipe bracket module unit. The ice making calandria is a round steel pipe, and the ice making calandria is connected in parallel and finally connected with the ice making equipment.

In this embodiment, the ice making tube notches 2 are arranged in rows or in columns according to the position of the ice making calandria. The distance between the notches 2 of the ice making tubes in adjacent rows or adjacent columns is suitable for the distance between the ice making tubes.

In this embodiment, the water permeable holes 1 are hexagonal holes, and may be circular or polygonal holes. The permeable holes 1 are arranged under the supporting subunits 6, and the opening areas of the permeable holes 1 are adapted to the design cross-sectional areas when the ice making is permeable. The small round holes 3 that permeate water are designed at intervals between the support subunits 6 of three hexagons, and when the support subunits 6 are quadrangles, the small round holes 3 that permeate water are arranged between the support subunits 6 of four quadrangles, and the small round holes 3 that permeate water are arranged at the bottom of the support subunits 6.

In this embodiment, the concatenation socket contains long limit concatenation socket 4 and minor face concatenation socket 5, and long limit concatenation socket 4 and minor face concatenation socket 5 are trapezoidal socket. The long-edge splicing insertion openings 4 are formed in the base supports 7 of the two opposite long edges of the ice making pipe carrier module unit, and the short-edge splicing insertion openings 5 are formed in the base supports 7 of the two opposite short edges of the ice making pipe carrier module unit. The long edge splicing sockets 4 arranged opposite to the edges are arranged in a staggered mode, and the short edge splicing sockets 5 arranged opposite to the edges are arranged in a staggered mode.

In the embodiment, the base supports 7 are supporting plates which are square plates, the shapes and the sizes of the supporting plates are suitable for the shapes and the sizes of the ice pipe support module units, and the two base supports 7 are detachably connected; the bottom surface interval of base support 7 is provided with fixed block 8, and fixed block 8 is the linoleum.

As shown in fig. 3, the supporting subunit 6 is hexagonal or quadrangular columnar. In the support subunit 6 of ice-making pipe bracket modular unit or adjacent ice-making pipe bracket modular unit, support subunit 6 and can dismantle the connection through grafting, cup joint or joint.

In this embodiment, the opposite sides of the supporting sub-unit 6 are provided with the ice making tube notches 2, and the length of each side of the supporting sub-unit 6 is greater than the length of the ice making tube notch 2. The length of the notch 2 of the ice making pipe is adapted to the diameter of the ice making calandria. The notch 2 of the ice making pipe is an arc notch, and the radian of the arc notch is suitable for installing an ice making calandria; the distance between the top of the arc-shaped notch and the top of the supporting subunit 6 is larger than the diameter and the length of the ice-making calandria.

With reference to fig. 1 to 3, the construction method of the movable assembled ice-making pipe bracket is further described, which includes the following specific steps:

step one, according to the size of the required ice surface, combining the size of ice making pipe bracket module units, and adopting a sufficient number of ice making pipe bracket module units to form the area required by the ice surface; the notches 2 of the ice making tubes on the supporting subunits 6 are arranged in rows or columns, and the size of the supporting subunits 6 is correspondingly set according to the width between the adjacent ice making tube rows.

Paving ice making pipe bracket module units, and splicing the long-edge splicing insertion opening 4 or the short-edge splicing insertion opening 5 with the ice making pipe bracket module unit which is installed firstly by the aid of the later-installed ice making pipe bracket module unit; the long-edge splicing sockets 4 or the short-edge splicing sockets 5 opposite to the joints of the adjacent ice pipe bracket module units are arranged in a staggered mode, and are inserted into grooves reserved in the base bracket 7 during installation, and the joints are guaranteed to be spliced into the supporting subunit 6.

Laying ice making calandria along the ice making pipe notch 2 on the support subunit 6, ensuring the linearity and fastening degree after laying, and checking that all laid ice making pipe bracket module units are not separated; the bottom surface and/or the side surface of the notch 2 of the ice making pipe is provided with a concave-convex surface or a rough surface.

Step four, ice making and watering are carried out, water permeates through the small circular water permeable holes 3 and the water permeable holes 1 and permeates below the base support 7, wherein the fixing block 8 is connected with a lower structure, and lateral anti-sliding limiting is added; when the water freezes into ice it forms a frozen whole with the substructure.

And step five, when the ice field is dismantled, the ice making calandria is recycled after ice is melted, and the ice making pipe bracket module units can be dismantled one by one and then recycled or treated in a centralized way after being dismantled.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that may be made by those skilled in the art within the technical scope of the present invention will be covered by the scope of the present invention.

Claims (10)

1. A movable assembled ice making pipe bracket is characterized by comprising a group of detachably connected ice making pipe bracket module units; the ice making pipe bracket module unit comprises a group of supporting subunits (6), ice making pipe notches (2) arranged on the supporting subunits (6), water permeable holes (1) arranged at the lower parts of the supporting subunits (6), small round water permeable holes (3) arranged between the adjacent supporting subunits (6), splicing jacks arranged at the periphery of the supporting subunits (6) and a base bracket (7) connected to the bottom of the supporting subunits (6); an ice making calandria is arranged in the ice making pipe notch (2).

2. A movable assembled ice-making tube tray as claimed in claim 1, wherein the supporting sub-units (6) are hexagonal or quadrangular columns, and the supporting sub-units (6) in the ice-making tube tray module unit are integrally manufactured or the supporting sub-units (6) in the adjacent ice-making tube tray module units are detachably connected.

3. A movable assembled ice making tube tray as claimed in claim 1, wherein the support sub-unit (6) is provided with ice making tube notches (2) at opposite sides thereof, and each side of the support sub-unit (6) is longer than the length of the ice making tube notch (2); the length of the ice making pipe notch (2) is adapted to the diameter of the ice making calandria.

4. A movable assembled ice making tube tray as claimed in claim 2, wherein the ice making tube notches (2) are arranged in rows or columns, and the distance between the ice making tube notches (2) in adjacent rows or columns is adapted to the designed distance between the ice making tubes.

5. The movable assembled ice making pipe bracket according to claim 4, wherein the ice making pipe notch (2) is an arc notch, and the radian of the arc notch is suitable for installing ice making calandria; the distance between the top of the arc-shaped notch and the top of the supporting subunit (6) is larger than the diameter and the length of the ice-making calandria.

6. The movable assembled ice making tube tray as claimed in claim 1, wherein the water permeable holes (1) are circular or polygonal holes, and the water permeable holes (1) are provided right under the supporting sub-unit (6); the opening area of the water permeable holes (1) is adapted to the design section area when the ice making is conducted and the water is permeable.

7. A movable assembled ice-making pipe bracket as claimed in claim 6, wherein the small circular water permeable holes (3) are designed at intervals between three hexagonal supporting sub-units (6) or four quadrangular supporting sub-units (6), and the small circular water permeable holes (3) are arranged at the bottom of the supporting sub-units (6) in the vertical direction.

8. The movable assembled ice making tube tray as claimed in claim 1, wherein the splicing insertion openings comprise long-side splicing insertion openings (4) and short-side splicing insertion openings (5), the long-side splicing insertion openings (4) are arranged on the base supports (7) at two opposite long sides of the ice making tube tray module unit, and the short-side splicing insertion openings (5) are arranged on the base supports (7) at two opposite short sides of the ice making tube tray module unit; the long edge splicing sockets (4) arranged opposite to the edges are arranged in a staggered mode, and the short edge splicing sockets (5) arranged opposite to the edges are arranged in a staggered mode.

9. The removable assembled ice-making tube tray as claimed in claim 8, wherein the base brackets (7) are support plates having shapes adapted to the ice-making tube tray module unit, and the two base brackets (7) are detachably connected; the bottom surface of the base bracket (7) is provided with fixed blocks (8) at intervals.

10. A construction method for applying the movable assembled ice-making pipe bracket as claimed in any one of claims 1 to 9, which is characterized by comprising the following specific steps:

step one, according to the size of the required ice surface, combining the size of ice making pipe bracket module units, and adopting a sufficient number of ice making pipe bracket module units to form the area required by the ice surface; the notches (2) of the ice making tubes on the supporting subunits (6) are arranged in rows or columns, and the sizes of the supporting subunits (6) are correspondingly set according to the widths of the adjacent ice making tube banks;

paving ice making pipe bracket module units, and splicing the long-edge splicing insertion opening (4) or the short-edge splicing insertion opening (5) with the ice making pipe bracket module unit which is installed firstly by the aid of the later-installed ice making pipe bracket module unit; the long-edge splicing sockets (4) or the short-edge splicing sockets (5) which are opposite to the joint of the adjacent ice pipe bracket module units are arranged in a staggered manner and are inserted into the reserved grooves during installation, and the joint is ensured to be spliced into a supporting subunit (6);

laying an ice making calandria along the ice making pipe notch (2) on the support subunit (6), ensuring the linearity and the fastening degree of the laid ice making pipe, and checking that all laid ice making pipe bracket module units are not separated; the bottom surface and/or the side surface of the notch (2) of the ice making pipe are/is provided with a concave-convex surface or a rough surface;

fourthly, making ice and watering, wherein water seeps below the base support (7) through the small circular water-permeable holes (3) and the water-permeable holes (1), the fixing block (8) is connected with a lower structure, and lateral anti-skidding limiting is added; when the water is frozen into ice, the water and the lower structure form a frozen whole;

and step five, when the ice field is dismantled, the ice making calandria is recycled after ice is melted, and the ice making pipe bracket module units can be dismantled one by one and then recycled or treated in a centralized way after being dismantled.

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